Method and apparatus for v-bank filter bed scanning

ABSTRACT

Embodiments of the invention generally related to a method and apparatus for scanning a v-bank filter. In one embodiment, a method for testing a v-bank filter includes providing an aerosol challenge to an upstream side of a v-bank filter, scanning a downstream side of the v-bank filter with a probe having one or more rectangular sample ports, and providing samples taken through the probe during scanning to a test instrument. In yet another embodiment, a probe for scanning a v-bank filter is provided that includes a body having a plurality of rectangular sample ports. Each sample port is tapered to a port configured to connect to a sample tube. The long sides of the rectangular sample ports are arranged in a stacked parallel orientation.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 11/552,409 filed Oct. 24, 2006 by Morse, et al, which claims benefit of U.S. Provisional Patent Application Ser. No. 60/729,643, filed Oct. 24, 2005 Morse, both of which are incorporated by reference in their entireties.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to a method and apparatus for v-bank filter bed scanning.

2. Description of the Related Art

Many contamination control applications having high airflow requirements utilize v-bank filters over panel filters when laminar flow is not of primary concern. However, conventional manufacturing and validation practices limit testing of v-bank to overall efficiency test due to the inability to accurately leak test (i.e., scan test) the filter media for pin hole leaks. The inability to scan test v-bank filters has been documented in an article published October, 2001 in Cleanrooms Magazine entitled “EN1822: THE STANDARD THAT GREATLY IMPACTED THE EUROPEAN CLEANROOMS MARKET.” In the article, the author states that “ . . . HEPA/ULPA filters with V-shaped pleat packages cannot be scanned, because the measuring probe cannot be brought close enough to a possible leak in the pleated package.”

However, many facilities are forced to utilize deep pleated filter products instead of v-bank filter products because of increasingly stringent validation requirements for contamination control that require scan testing. As deep pleated filters generally do not have the air handling capacity of v-bank filters, more filters may be required for a given application, and more energy may be required to drive gas flows through the filters. Thus, the use of deep pleated filters in applications where v-bank filters could be utilized may realize higher filter and energy usage costs.

Therefore, there is a need for a method and apparatus for scanning v-bank filter beds.

SUMMARY OF THE INVENTION

Embodiments of the invention generally related to a method and apparatus for scanning a v-bank filter. In one embodiment, a method for testing a v-bank filter includes providing an aerosol challenge to an upstream side of a v-bank filter, scanning a downstream side of the v-bank filter with a probe having one or more rectangular sample ports, and providing samples taken through the probe during scanning to a test instrument.

In another embodiment, a method for testing a v-bank filter includes providing a challenge to a v-bank filter having at least two adjacent banks of filter media arranged in a “v” configuration, scanning a probe across an opening defined between the adjacent banks of filter media, wherein the probe is moved in a direction predominantly perpendicular to a short side of a sample port of the probe, sampling air passing through the banks of filter media and into the probe, and determining if a sample is indicative of a leak.

In yet another embodiment, a probe for scanning a v-bank filter is provided that includes a body having a plurality of rectangular sample ports. Each sample port is tapered to a port configured to connect to a sample tube. The long sides of the rectangular sample ports are arranged in stacked in a parallel orientation.

BRIEF DESCRIPTION OF THE DRAWINGS

The teachings of the present invention can be readily understood by considering the following detailed description in conjunction with the accompanying drawings, in which:

FIGS. 1A-B, 2-3, 4A-B, 5A-B and 6 are various views of different embodiments of a probe suitable for scan testing a v-bank filter;

FIG. 7 is another embodiment of a probe suitable for scan testing a v-bank filter;

FIGS. 8-11 are images of a probe of the present invention engaged with a v-bank filter to facilitate scan testing;

FIGS. 12A-B are another embodiment of a probe suitable for scan testing a v-bank filter;

FIGS. 13A-C are another embodiment of a probe suitable for scanning a v-bank filter;

FIG. 13D is another embodiment of a probe suitable for scanning a v-bank filter;

FIG. 14 is a screen shot illustrating graphic test results of a v-bank filter scanned in a direction parallel to long axis of a probe without the edges of the probe extending over the frame of the filter;

FIG. 15 is a screen shot of a chart corresponding to the graphic test results of FIG. 14;

FIG. 16 is a screen shot illustrating graphic test results of the v-bank filter retested after changing the filter orientation 180 degrees; and

FIG. 17 is a screen shot of a chart corresponding to the graphic test results of FIG. 16.

To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.

It is to be noted, however, that the appended drawings illustrate only exemplary embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.

DETAILED DESCRIPTION

Embodiments of the invention are suitable for scan testing v-bank filters for pin-hole leaks. Although the filter illustrated herein is a FILTRA 2000™ v-bank filter available from Camfil Farr, Inc., it is contemplated that the testing apparatus and method may be utilized to scan test v-bank filters having other configurations. A scan probe developed to facilitate scan testing enables reasonable scan rate (i.e., in the range of about 1-2 inches per second (25.4-50.8 millimeters per second)) for manual scan operations and may further be adapted for use in automatic or semi-automatic scan applications.

Probe Design

The V-bed media pack configuration creates obstacles in the scan test process and probe design, as compared to a conventional box-style media packs, where the face of the entire pack is in a single plane. In conventional box-style filters, the probe generally consists of a tube with an integral transition through which the sample is drawn. The transition is generally square or rectangular. The design of this type of sampling probe is such that the localized velocities across the sampling plane of the probe are equivalent, resulting in uniform airflow across the sampling plane.

In the present invention, a probe allows adjacent media packs to be scanned simultaneously. Although this isn't necessary, it is desirable because it reduces the number of “passes” per filter that an operator has to make with the probe when testing a filter. It is contemplated that the probe may be configured to scan only one media pack in a single pass.

FIGS. 1-8 depict various views of probes suitable for scan testing a v-bank filter. The samples taken during the scan may be utilized for determining the location of pin-hole leaks greater than a predetermined criteria or filter efficiency. Referring first to a probe 100 depicted in FIGS. 1A-B, the probe 100 is generally a tube or other hollow body 102 sealed at a first end 104 and having a port 106 at a second end 108. The shape of the body 102 is configured to allow the first end 104 of the probe 100 to be positioned between adjacent banks of a v-bank filter. The port 106 is generally adapted to coupling to a test instrument, such as a photometer, particle counter or other instrument suitable for leak detection or efficiency measurement. In one embodiment, a length of stainless steel tubing is bent into a configuration that fits into the “V” defined by the filter banks, for example, a “V” or triangle shape. In other embodiment, the tubing may be straight or wedge shaped. A plurality of apertures 110, such as holes or slots, are formed, for example by drilling, along outward facing side of at least one leg of the probe 100. The number, size and spacing of the apertures 110 are selected to allow sampling along the length of the media bank perpendicular to the direction of scan. As such, the length of the probe having the apertures 110 formed therethrough is generally equal to the length of the media bank for which the probe is intended to be used. Thus, the apertures 110 on each leg face in opposite directions. In the embodiment depicted in FIG. 1, each leg of the probe 100 includes a linear arrangement of apertures 110. The interior volume of each leg is fluidly coupled to the port 106 such that samples taken through the apertures 110 may be provided to the test instrument.

The apertures 110 may be of a single, different or a combination of sizes. In one embodiment, the orifice, or plan area of the apertures 110 formed through the probe wall is reduced between holes extending along the length of the probe towards the first end 104 to account for pressure losses due to the sample being drawn from the second end 108 of the probe. In one embodiment, the apertures 110 include at least two groups of holes and/or slots having different orifice sizes. In the embodiment depicted in FIG. 1B, the apertures 110 include a far group of holes 110C at the first end 104 of the probe 100 furthest from the photometer that have a larger diameter (orifice) than the diameter of a near group of holes 110A disposed closest to the second end 108 (and photometer), while a middle group of holes 110B disposed in the midsection of the probe 100 have a diameter somewhere between those the diameters of the apertures 110 closest and farthest from the second end 108. For example, the apertures 110 may include near group of holes 110A having a diameter of about 0.018-0.062 inches (0.45-1.57 mm), middle group of holes 110B having a diameter of about 0.055-0.077 inches (1.40-1.96 mm), and a far group of holes 110C having a diameter of about 0.062-0.093 inches (1.57-2.36 mm). Increasing the hole diameter along the length of the probe 100 results in a more uniform (and representative) sample along the length of the probe. Similar probes could be designed using an aperture 110 configured as a slot that changes in width along the length of the probe (e.g., tapers towards the first end 104), or by using perforated material along the length of the probe that uses larger holes and/or different hole spacing along the length of the probe, in order to achieve the same results.

FIGS. 2-3 show the probe 100, including an integral handle 150 and guides 112 to locate the probe 100 in the “V” of the filter during a scan of the filter. These guides 112 allow the probe 100 to maintain at a predefined distance from each media pack by limiting the distance the first end 104 of the probe can be inserted into the filter. The guides 112, such as bars, rods, rollers, bearing, slides, tabs or other fixtures (as seen in FIGS. 2-3 and 8-11), ensure the probe remains reasonably centered between the media packs, thereby eliminating potential damage the media banks by inadvertent contact with the probe 100 during insertion or scanning, and also ensuring that the distance between the probe and the face of the media pack is maintained at the required distance (or range).

In one embodiment, the probe 100 is fabricated from one or more hollow tubes 180 formed in a V-shape to fit between the pleated media packs. The tubes 180 are coupled near the second end 106 at a tee 182, which extends to the port 108. The apertures 110 of the probe may be designed as a plurality of slots or holes 110A-C (as shown in FIGS. 1A-B, and 2-3), staggered holes 410 (as shown in FIGS. 4A-B), one or more tapered slots 510 (as shown in FIGS. 5A-B), staggered slots or holes 610 (as shown in FIG. 6) or other configurations to allow air sampling within 1″ (25.4 mm) of the face of the media pack, which is generally an industry acceptable distance between the media pack and a sampling probe. In embodiments wherein a slot is utilized, the aperture 110 may be a single slot 510 as shown in FIGS. 5A-B, although a plurality of slots may be utilized. The geometry of the probe 100 may be modified in cases where standards or industry practices would require that the probe be located closer to the media pack during scan testing. In embodiments wherein the body 102 is a tube 180, the rounded surface (outer diameter of the tube 180) through which the apertures 110 are formed provides protection against damage to the filter media in the advent that inadvertent contact between the probe and media is made, particularly as compared to conventional rectangular probes having squared corners.

In the embodiment depicted in FIG. 4A-B, a probe 400 includes a body 102 having legs 402, 404 that meet at a first end 104. The legs 402, 404 flare outward from the first end 104 toward a second end 108. Each of the legs 402, 404 includes a separate port 406A, 406B at the second end 108 for coupling each leg separately to a test instrument. Since samples taken through apertures 410 (formed in the legs 402, 404 as described above) are separately sampled, leak detection of the specific bank of filter media proximate an individual leg 402, 404 may be determined.

The apertures 410 may be staggered in size so that the apertures having larger orifice diameters are closer to the first end 104. In one embodiment, the apertures 410 are configured similar to the apertures 110 described with reference to FIG. 1B.

In another embodiment depicted in FIGS. 5A-B, a probe 500 includes a body 102 that may be configured as either the probe 100 or 400 described above. The probe 500 includes a slot 510 formed in the outward facing sides of the legs of the body 102. In one embodiment, the slot 510 may be tapered such that the wide end of the slot 510 is proximate the first end 104 of the body 102.

In another embodiment depicted in FIG. 6, a portion of a probe 600 is shown. The body 102 of the probe 600 that may be configured as either the probe 100 or 400 described above. The probe 600 includes a plurality of staggered apertures 610, shown in FIG. 6 as slots. The apertures 610 formed in the outward facing sides of the body 102 such that a portion of one aperture 610 overlaps the adjacent aperture. In one embodiment, the apertures 610 closer the first end (104) of the body 102 may have more in open area than the apertures 610 is proximate the second end (106).

In another embodiment depicted in FIG. 7, the probe 700 has a rectangular shape. In one embodiment, the width of the probe is such that it wider than the width of the slot 702 defined at the wide end of the Vee where air exits between the media packs 704 of a v-bank filter. The probe 700 may include one or more guides 706 to align the probe with the slot, such as a rod, roller, bar or other locating features coupled to the open end of the probe 706 as shown in FIG. 7. The probe 700 is placed as near as possible to the slot 702 in order to eliminate potential bypass around the probe. Scan testing is conducted by moving the probe along the slot. This is very similar to scan testing a conventional HEPA filter, except the probe is used to scan the slot instead of the media pack. It is contemplated that scan data may also be utilized to calculate filter efficiency.

In another embodiment depicted in FIGS. 12A-B, a probe 1200 suitable for scanning a v-bank filter is illustrated. The probe 1200 includes a body 1202 having at least one sample port 1204. In the embodiment depicted in FIGS. 12A-B, four sample ports 1204 are shown.

Each sample port 1204 includes a sample entrance port 1206 and a sample exit port 1208. A fitting 1210 is coupled to the body 1202 at the exit port 1208 to facilitate coupling the port 1204 to a test instruments, such as a photometer or other suitable device.

At least one guide 1212 is provided on the sample entrance port side of the probe 1200. The guide 1212 facilitates alignment of the probe 1200 to the filter as described above. In the embodiment depicted in FIGS. 12A-B, two guides 1212 in the form of bars secured perpendicular to the major axis of the probe 1200 and aligned with the scan direction are provided.

FIGS. 13A-C depict another embodiment of a probe 1300 having a rectangular shape. The probe 1300 has a flared opening or sampling port defined by a short side 1302 and a long side 1304. The tapered closed side of the probe 1300 is configured with a port that allows connection of the probe 1300 to test equipment via a sample line 1306. The probe 1300 is configured such that the short side 1302 is much smaller than the width of the slot 702 defined at the wide end of the Vee where air exits between the media packs 704 of a v-bank filter.

Optionally, a probe 1320 may be configured with multiple sampling ports 1322 arranged such that the long sides 1304 of the samples ports 1322 are stacked parallel, as shown in FIG. 13D. The probe 1320 may be formed from a unitary mass of material, or be comprised of an assembly of components. The probe 1320 allows samples to be taken from a greater area of the filter during each pass of the probe, optionally to include simultaneous sampling of from adjacent media packs, and as a further option when as shown in FIG. 13E, simultaneously from multiple Vees using probes 1320 separated by spacers 1324. The length of the spacers 1324 are generally selected such that the probes 1320 are aligned with the Vees without extending beyond the packs 704 of the v-bank filter.

The probe 1300 is placed in the slot 702 in a orientation such that the long side 1304 of the probe 1300 is parallel with the length of the slot 702 so that the probe has a long dwell time over the pack 702 in the direction of scanning. This is very similar to scan testing a conventional HEPA filter, except the probe is used to scan the slot in a direction perpendicular to the short side 1302 of the probe 1300. It is contemplated that scan data may also be utilized to calculate filter efficiency.

Validation of Probe & Method of Testing V-Bank Filter

The probe of the present invention was demonstrated as being effective for locating leaks. A FILTRA 2000 v-bank filter was utilized during the test. The filter was installed in a test rig and challenged with PAO. The filter was then manually scan tested using the probe described above. The testing is detailed below.

Procedure—Insertion Style Probe

In one embodiment, a probe, such as the probes 100, 400, 500, was utilized to scan test a Filtra 2000™. The probe was used to scan the between the banks of filter media within the Vee's from the downstream side of the V-bed filter.

Two holes were intentionally placed in a FILTRA 2000™ v-bank filter using a mechanical pencil with a 0.5 mm diameter lead to create a leak in a known location. “Hole A” was created in the media pack on the downstream side of the filter, on the downstream side of the media pack, at a location approximately 1 inch (25.4 mm) from the vertical extrusion member. “Hole B” was created in the media pack on the upstream side of the filter, on the upstream side of the media pack, at a location very near the vertical extrusion member. Holes were created in those locations because they represent locations where leaks are generally considered difficult to detect.

The test rig utilized to perform the scan test generally includes a variable frequency drive on the test rig was adjusted until a pressure drop across the air flow station (AFS) was approximately 0.452 inches water gage (w.g,) (0.113 kPa) as measured using an Alnor Micromanometer. This pressure drop across the filter is indicated of approximately 2000 cubic feet per minute (56.6 cubic meters per minute) of flow through the filter.

An ATI TDA-5B thermal generator was used to generate PAO aerosol that was injected into the inlet of the blower. An ATI TDA-2E photometer was used to obtain an upstream sample in the transition immediately upstream of the filter. The blower, aerosol generator and photometer were allowed to warm up for approximately 20 minutes allow steady-state operation to be reached.

The aerosol generator was turned on, and adjusted to obtain between 40-50 micrograms/liter. This range was chosen because various industry standards and recommendations (for examples, IEST and ATI) recommend scanning with an aerosol challenge ranging from 10-100 micrograms/liter. The upstream challenge concentration was measured with the photometer. The filter was scan tested using the prototype probe connected to the photometer and the results were recorded as shown in Table 1 below. The scan was performed by manually inserting the probe into the filter such that the aperture(s) is facing the filter pack to be tested. The probe is then advanced across the pack to test the media for pin-hole leaks. The leak threshold may be set per IEST standards or other test protocol.

Equipment Used

-   -   Test Filter: FILTRA 2000™, available from Camfil Farr, Inc.         -   Model Number: FA1570A-01-01-09         -   Part Number: 855010095         -   Serial Number: A116084-008         -   Label Efficiency: 99.998%         -   Label Pressure Drop: 1″ w.g. (0.25 kPa)         -   Rated cfm: 2150 (60.9 cubic meters per minute)     -   Pressure Indicator: ALNOR MicroManometer (digital         micromanometer)         -   Model: AXD 550         -   Instrument I.D.: 66303         -   Calibrated: Jun. 26, 2003         -   Calibration Due: Jun. 26, 2004     -   Leak Detection Equipment: ATI Analog Photometer         -   Model: TDA-2E         -   Serial No.: 8462         -   Calibrated: Oct. 31, 2003         -   Calibration Due: Oct. 31, 2004     -   Aerosol Generators:         -   ATI Thermal Generator             -   Model: TDA-5B             -   Serial No.: 15769         -   ATI Laskin Nozzle Generator             -   Model: TDA-4BL

Serial No.: 14718 TABLE 1 Parameter Result AFS dP: 0.452 System Flowrate ˜2000 cfm (56.6 cubic meters per minute) Aerosol Type Thermal PAO Upstream Aerosol Concentration 40 μg/l Photometer Scale Setting  0.1% Approximate Manual Scan Speed ˜1 in/sec (25.4 mm/sec) “Hole A” Leak Detected** “Hole B” Leak Detected** Background Concentration* 0.04% *The “background concentration” was constantly present and attributed to the so-called “Bleed Through” phenomena. Essentially, it's a result of using thermally generated aerosol (with a particle diameter near the most penetrating particle size (MPPS), or 0.12 μm) for the challenge and operating the filter at such a high flowrate. The IEST recommendations were developed for systems operating at # approximately 90 feet per minute (fpm) (27.4 meters per minute) superficial velocity. In this test, the superficial media velocity is approximately 160 fpm (48.8 meters per minute). Furthermore, per IEST-RP-CC034.1, a Laskin nozzle generator (generating particles in the range of 0.6-0.7 μm diameter) is recommended for challenging this type of filter. **IEST-RP-CC034.1 specifies a maximum penetration of 0.01%. It was not possible to base the presence of a leak on that penetration since the “background concentration” was higher than 0.01%. However, when the probe passed over the leaks, the photometer registered penetrations exceeding 0.1%, obviously indicating that leaks were present.

After scan testing was completed using an upstream challenge of approximately 40 μg/l, the output to the aerosol generated was adjusted to approximately 10 μg/l, and the filter was scanned again. That test yielded the same results as the test conducted at 40 μg/l. In order to be consistent with recommendations of IEST-RP-CC0034.1, testing was conducted using an ATI TDA-4BL Laskin Nozzle Generator. The results of that test are shown in Table 2. TABLE 2 Parameter Result AFS dP: 0.452 System Flowrate ˜2000 cfm (56.6 cubic meters per minute) Aerosol Type Cold PAO Upstream Aerosol Concentration 12 μg/l Photometer Scale Setting 0.01% Approximate Manual Scan Speed ˜1 in/sec (25.4 mm/sec) “Hole A” Leak Detected** “Hole B” Leak Detected** Background Concentration n/a

The “background concentration” due to bleed-through was not a problem when testing with the Laskin Nozzle generator. “Hole A” and “Hole B” were easily detected. Thus, due to “bleed through” effects, there is a background concentration present during testing using thermally generated PAO, which exceeds the maximum allowable penetration as recommended by IEST-RP-CC0034.1. This may be overcome by using a higher efficiency filter, such as an ULPA filter, which is designed to be highly efficient in removing 0.12 μm particles. The down side of this is the increase in pressure drop and increase in cost. As designed, the probe is effective in locating small pinhole leaks in the filter, with the filter operating at design flowrates and challenged with cold PAO generated with a Laskin Nozzle generator.

Procedure—Above Slot Style Probe

In another embodiment, the probe such as the probes 700, 1200 was utilized to scan test a Filtra 2000™. The probe was used to scan the opening between the Vee's on the downstream side of the V-bed filter without penetrating between the Vee's. The probe height was designed so that it extended beyond the media pack and overlapped the channel on each side of the Vee. For the test data provided below, the opening of the inlet sample port 1206 is 5.406 inches high×0.125 inches wide (137 mm×3.18 mm).

Design of the probe was confirmed as effective in locating leaks using a Filtra 2000™ was installed in a test rig and challenged with PAO. The filter was automatically scanned with the probe assembly that was coupled to a lead screw assembly which was rotated by a small servo motor. This allowed for precise control of the rotational speed of the motor and therefore accurate and precise control of the linear speed of the probe assembly. The testing is detailed below.

Two holes were intentionally placed in a Filtra 2000 using capillary tubes with an internal diameter (I.D.) of 0.020″. “Hole 1” was created in the media pack on the downstream side of the filter, on the downstream side of the media pack, at a location approximately 6″ from the side of filter. “Hole 2” was created in the media pack on the upstream side of the filter, on the upstream side of the media pack, at a location approximately 1″ from the side of the filter. Holes were created in those locations because they represent locations where leaks are generally difficult to detect.

The variable frequency drive on the test rig was adjusted until the flowrate was approximately 2,400 cfm. An ATI TDA-4B Lite aerosol generator was used to generate PAO aerosol that was injected through the aerosol injection ring in the containment housing. The autoscan control and sampling system was used to conduct leak testing using a Lighthouse Solair 3100+ laser particle counter on the 0.3 micron size range. Results are provided in the Table below. TABLE 3 Test Results Operating at 0.25 inches/sec Scan Speed Parameter Result System Flowrate 2,400 cfm (70 meters per minute) Aerosol Type Cold PAO Upstream Aerosol Concentration 460,000,000 particles per cubic foot (13,025,750 particles per cubic meter) (0.3 micron diameter) Scan Speed 0.25 in/sec (.64 cm/sec) “Hole 1” Leak not detected “Hole 2” Leak not detected

TABLE 4 Test Results Operating at 0.125 inches/sec Scan Speed Parameter Result System Flowrate 2,400 cfm (70 meters per minute) Aerosol Type Cold PAO Upstream Aerosol Concentration 460,000,000 particles per cubic foot (13,025,750 particles per cubic meter) (0.3 micron diameter) Scan Speed 0.125 in/sec (0.32 cm/sec “Hole 1” Leak detected @ 6.6″ with 0.014″ penetration “Hole 2” Threshold leak detected with 0.9″ of 0.008% penetration

As designed, at rated airflow of 2,400 cfm and an upstream challenge concentration of 460,000,000 particles per cubic foot of 0.3 micron diameter, the system was capable of locating pinhole leaks at a scan speed of 0.125 inches/sec, but not 0.250 inches/sec. Using higher aerosol challenge upstream may allow leaks to be located at faster scan speeds, since the amount of challenge coming through the leak would be higher and detected more easily. Also, at lower airflows the system is capable of finding leaks at faster scan speeds since the particles passing through the pinhole are not diluted downstream of the filter by clean air and are thus more easily detected during scanning.

Scan speeds of up to about 0.1875 inches/sec (0.48 cm/sec) have demonstrated to produce acceptable scanning results. Thus, in systems having an operational velocity of less than or equal to 2400 cubic feet per minute, a scan speed of less than or equal to about 0.1875 inches per second may be utilized to detect leaks in v-bank filters wherein the upstream challenge is about 300,000,000 particles per cubic foot (about 8,495,050 particles per cubic meters) in a 2,400 cfm flow. It is contemplated that the scan rate may rise at lower operational velocities and/or at higher challenges.

In another embodiment, the probe such as the probe 1300 was utilized to scan test a Filtra 2000™. The probe was used to scan the opening between the Vee's on the downstream side of the V-bed filter without penetrating between the Vee's. The probe was oriented so that it does not extend beyond the media pack or overlapped the channel on each side of the Vee, as shown in FIG. 13A.

Tests were conducted with a Filtra 2000 installed in a CamContain™ (integrated) system having an aerosol injection and autoscan mechanism. The aerosol challenge, scan speeds and challenge concentration may be as described above. The CamContain™ housing was connected to a blower using spiral ductwork. The flow rate was measured using an airflow station. The CamContain™ control system was used to leak test the filter. TABLE 5 Test Details System Flow rate (cfm) 2,150 cfm Aerosol Type Cold PAO Scan Speed (inches/sec) 0.125 Particle Diameter (microns) 0.3 Particle Counter Model Lighthouse Solair 3100+ Particle Counter Flow rate (cfm) 1 Particle Counter Calibration Date Particle Counter Due Date

TABLE 6 Filter Details Serial Number A980122-005 Model Number FA1570A-01-01-09/18/20/21,24X Part Number 855010101 Rated Flow (cfm) 2,150 ΔP at Rated Flow (in. w.g.) 1.0

The V-bank filter was installed in the test unit with the Vees in a vertical orientation with the filter label oriented towards the front of the housing. The flow rate through the filter was about 2,150 cfm. A laskin nozzle with PAO was used to generate an upstream concentration of about 224,520,235 particles per cubic foot. As shown in graph 1400 of FIG. 14, line 1402 indicates potential leak threshold (N_(p)) as defined in IEST-RP-CC034.2. Line 1404 represents samples taken through the probe 1300 and exceeds the threshold at a position near 14 inches, as indicated by reference numeral 1306.

FIG. 15 is a chart 1500 that corresponds with the graph 1400 shown in FIG. 14. The chart 1500 is a summary of measurements exceeding the threshold value of N_(p). As show, there were four measurements that exceed Np. The actual number of particles measured at each of the four locations ranges from 398 to 432. These readings were based on a 1 second sample period using a 1 cfm particle counter.

The percent penetration (% Pt) of the leak may be calculated are follows: $\begin{matrix} {{\%\quad{Pt}} = {\frac{\begin{pmatrix} {\left( {\#\quad{ofparticles}\text{/}\sec} \right) \times 60\quad\left( {\sec\text{/}\min} \right) \times} \\ {{particlecounterflowrate}\quad\left( {{ft}^{3}\text{/}\min} \right)} \end{pmatrix}}{{upstreamconcentration}\quad\left( {{particle}\text{/}{ft}^{3}} \right)} \times 100}} & (1) \end{matrix}$ where the number of particles per second is the number of particles sample by the probe during a 1 second sample period. This value is shown in the table as Particle Cnt, the particle counter flow rate in cubic feet per minute (cfm); and the upstream concentration is the upstream aerosol concentration in particles per cubic foot and is shown in the table as U.S. Conc.

Thus, % Pt 14.49″ and 14.62″ is: ${\%\quad{Pt}} = {{\frac{432\quad\left( {{particles}\text{/}\sec} \right) \times 60\quad\left( {\sec\text{/}\min} \right) \times 1\quad\left( {{ft}^{3}\text{/}\min} \right)}{224,520,235\quad\left( {{particle}\text{/}{ft}^{3}} \right)} \times 100} = {0.012\quad\%}}$

The filter in the housing was later rotated 180 from the original orientation and a scan test was conducted. The results are shown in a graph 1600 of FIG. 17. The flow rate through the filter was about 2,150 cfm. A laskin nozzle with PAO was used to generate an upstream concentration of about 280,290,608 particles per cubic foot. Line 1702 indicates potential leak threshold (N_(p)) as defined in IEST-RP-CC034.2. Line 1704 represents samples taken from the probe 1300. As indicated by reference numerals 1706, a leak was detected by the probe.

Chart 1700 of FIG. 17 corresponds with the graph 1600 shown in FIG. 16. Chart 1700 is a summary of measurements exceeding the threshold value of N_(p). As show, there were two measurements that exceeded Np. The number of particles measured at the leak point is 470. This reading was based on a 1 second sample period using a 1 cfm particle counter.

The percent penetration (% Pt) of the leak may be calculated by Equation 1. ${\%\quad{Pt}} = {{\frac{470\quad\left( {{particles}\text{/}\sec} \right) \times 60\quad\left( {\sec\text{/}\min} \right) \times 1\quad\left( {{ft}^{3}\text{/}\min} \right)}{280,290,608\quad\left( {{particle}\text{/}{ft}^{3}} \right)} \times 100} = {0.010\quad\%}}$

Thus, a method and apparatus has been provided that enables scan testing of v-bank filters. Advantageously, the invention will allow the use of v-bank filters in applications where testing for pin-hole leaks is required.

Although various embodiments which incorporate the teachings of the present invention have been shown and described in detail herein, those skilled in the art can readily devise many other varied embodiment that still incorporate these teachings. 

1. A method for testing a v-bank filter, comprising: providing an aerosol challenge to an upstream side of a v-bank filter; scanning a downstream side of the v-bank filter with a probe having one or more rectangular sample ports; and providing samples taken through the probe during scanning to a test instrument.
 2. The method of claim 1, wherein scanning further comprises: moving the probe primarily in a direction perpendicular to a short side of the sample port.
 3. The method of claim 2, wherein scanning further comprises: moving the probe at a speed of about 1-2 inches per second (25.4-50.8 millimeters per second) across the filter while scanning.
 4. The method of claim 1 further comprising: sampling two facing media banks simultaneously.
 5. The method of claim 1 further comprising: sampling Vees of the filter simultaneously.
 6. The method of claim 9 further comprising: challenging the filter with an aerosol having a concentration of at least about 12 μg/l.
 7. The method of claim 1 further comprising: determining if the filter has a pin-hole leak from the samples.
 8. The method of claim 1 further comprising: determining an efficiency of the filter from the samples.
 9. A method for testing a v-bank filter, comprising: providing a challenge to a v-bank filter having at least two adjacent banks of filter media arranged in a Vee configuration; scanning a probe across an opening defined between the adjacent banks of filter media, wherein the probe is moved in a direction predominantly perpendicular to a short side of a sample port of the probe; sampling air passing through the banks of filter media and into the probe; and determining if a sample is indicative of a leak.
 10. The method of claim 9, wherein scanning further comprises: moving a second sample port formed in a body of the probe across a second opening.
 11. The method of claim 9, wherein scanning further comprises: moving the probe at a speed of less than about 0.1875 inches per second (0.48 cm/sec).
 12. The method of claim 9, wherein scanning further comprises: moving the probe at a speed of less than about 0.125 inches per second (0.32 cm/sec).
 13. The method of claim 9 further comprising: challenging the filter with at least about 300,000,000 particles per cubic foot (@ 8,495,050 particles per cubic meters).
 14. The method of claim 9 further comprising: providing at least about 2000 cfm (56.6 cubic meters per minute) of air flow through the filter.
 15. A method for testing a v-bank filter, comprising: providing a challenge to a v-bank filter having at least four adjacent banks of filter media arranged in a Vee configuration; scanning an opening defined between at least one pair of adjacent banks of filter media with a probe having a plurality of rectangular sample ports, wherein the probe is moved in a direction predominantly perpendicular to a short side of one of sample ports of the probe; sampling air passing through the banks of filter media and into the probe; and determining if a sample taken through on of the sample ports is indicative of a leak through the filter.
 16. The method of claim 15 further comprising: simultaneously scanning openings defined between adjacent banks of filter media.
 17. A probe for scanning a v-bank filter, comprising: a body having a plurality of rectangular sample ports, each sample port tapering to an port configured to connect to a sample tube, the long sides of the rectangular sample ports arranged in a stacked parallel orientation.
 18. The probe of claim 17, wherein the body is fabricated from a single mass of material. 